DESIGN AND ANALYSIS OF A SHOCK ABSORBER

Rohit Verma CADD CENTRE,AGRA

Abstract

A shock absorber or suspension system is a mechanical device designed to smooth out or damp shock impulse, and dissipate kinetic energy. The shock absorbers duty is to absorb or dissipate energy. In a vehicle, it reduces the effect of traveling over rough ground, leading to improved ride quality, and increase in comfort due to substantially reduced amplitude of disturbances. When a vehicle is traveling on a level road and the wheels strike a bump, the spring is compressed quickly. The compressed spring will attempt to return to its normal loaded length and, in so doing, will rebound past its normal height, causing the body to be lifted. The weight of the vehicle will then push the spring down below its normal loaded height. This, in turn, causes the spring to rebound again. This bouncing process is repeated over and over, a little less each time, until the up-and-down movement finally stops. If bouncing is allowed to go uncontrolled, it will not only cause an uncomfortable ride but will make handling of the vehicle very difficult. The design of spring in suspension system is very important. In this project a shock absorber is designed and a 3D model is created using CATIA V5. The model is also changed by changing the thickness of the spring. Structural analysis is done on the shock absorber by varying material for spring, Spring Steel and Beryllium Copper. The analysis is done by considering loads, bike weight, single person and 2 persons. Structural analysis is done to validate the strength and modal analysis is done to determine the displacements for different frequencies for number of modes. Comparison is done for two materials to verify best material for spring in Shock absorber.

Index Terms: damp shock, shock absorber.

1. INRODUCTION

A shock absorber or damper is a mechanical device designed to smooth out or damp shock impulse, and dissipate kinetic energy.

1.1 Description Pneumatic and hydraulic shock absorbers commonly take the form of a cylinder with a sliding piston inside. The cylinder is filled with a fluid (such as hydraulic fluid) or air. This fluid-filled piston/cylinder combination is a dashpot.

1.2 Explanation The shock absorbers duty is to absorb or dissipate energy. One design consideration, when designing or choosing a shock absorber, is where that energy will go. In most dashpots, energy is converted to heat inside the viscous fluid. In hydraulic cylinders, the hydraulic fluid will heat up, while in air cylinders, the hot air is usually exhausted to the atmosphere. In other types of dashpots, such as electromagnetic ones, the dissipated energy can be stored and used later. In general terms, shock absorbers help cushion cars on uneven roads. 1.3 Applications

Shock absorbers are an important part of automobile and motorcycle suspensions, aircraft landing gear, and the supports for many industrial machines. Large shock absorbers have also been used in structural engineering to reduce the susceptibility of structures to earthquake damage and resonance

1.4 Vehicle suspension In a vehicle, it reduces the effect of traveling over rough ground, leading to improved ride quality, and increase in comfort due to substantially reduced amplitude of disturbances. Without shock absorbers, the vehicle would have a bouncing ride, as energy is stored in the spring and then released to the vehicle, possibly exceeding the allowed range of suspension movement. Control of excessive suspension movement without shock absorption requires stiffer (higher rate) springs, which would in turn give a harsh ride. Shock absorbers allow the use of soft (lower rate) springs while controlling the rate of suspension movement in response to bumps.

1.5 Structures Applied to a structure such as a building or bridge it may be part of a seismic retrofit or as part of new, earthquake resistant construction. In this application it allows yet restrains motion and absorbs resonant energy, which can cause excessive motion and eventual structural failure.

1.6 Shock Absorber types There are a number of different methods of converting an impact /collision into relatively smooth cushioned contact..

Metal Spring Rubber Buffer Hydraulic Dashpot Collapsing safety Shock Absorbers Pneumatic Cylinders Self compensating Hydraulic

However the scope of work of this paper is restricted to Metal Spring Shock Absorber type only. 1.6.1 Metal springs Simply locating metal springs to absorb the impact loads are a low cost method of reducing the collision speed and reducing the shock loading. They are able to operate in very arduous conditions under a wide range of temperatures. These devices have high stopping forces at end of stroke. Metal springs store energy rather than dissipating it. If metal sprint type shock absorbers are used then measures should be provided to limit Oscillations. Metal springs are often used with viscous dampers. There are a number of different types of metal springs including helical springs, bevel washers(cone-springs), leaf springs, ring springs, mesh springs etc etc. Each spring type has its own operating characteristics.

1.7 Generalised Parameters for Helical spring Material: Spring Steel Beryllium Copper Mean diameter of a coil D=64mm Diameter of wire d = 8mm Total no of coils n= 15 Pitch=14mm Weight of bike = 125kgs Let weight of 1 person = 75Kgs Weight of 2 persons = 75×2=150Kgs Weight of bike + persons = 275Kgs Considering Factor of Safety(FOS)=1.5 Weight of Bike=200 kg(including FOS) Wt of Bike+2 persons=415 kg (including FOS) 2. MODEL OF SHOCK ABSORBER 2.1 Parts of Shock Absorber 2.1.1 Inner Part

2.1.2 Outer Part

2.1.3 Spring

2.1.4 Assembly of Shock Absorber

3.0 ANALYSIS RESULTS WITH PRESENT DESIGN 3.1 Analysis using material Spring Steel Material Properties: Young’s Modulus (EX): 210000N/mm2 Poisson’s Ratio (PRXY): 0.29 Density: 0.000007850kg/mm3 3.1.1Case A(1): Load 200kgs……Bike weight inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application Von Mises Stress Deformation

3.1.2Case A(2): Load 415kgs……Bike weight+Weight of 2 persons inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application

Von Mises Stress Deformation

3.2 Present Design-Analysis using material Beryllium Copper Material Properties: Young’s Modulus (EX): 280000N/mm2 Poisson’s Ratio (PRXY): 0.285 Density: 0.000001850kg/mm3 3.2.1Case A(1): Load 200kgs……Bike weight inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application

Von Mises Stress Deformation

3.2.2 Case A(2): Load 415kgs……Bike weight+Weight of 2 persons inclusive FOS Geometry imported from CATIA Meshed Model Fixed Support

Load Application

Von Mises Stress

Deformation

4.0 MODIFIED DESIGN 4.1 Parts of Shock Absorber 4.1.1 Spring – Spring Dia reduced to 6mm from 8mm

5.0 ANALYSIS RESULTS WITH MODIFIED DESIGN 5.1 Modified Design-Analysis using material Spring Steel Material Properties: Young’s Modulus (EX): 210000N/mm2 Poisson’s Ratio (PRXY): 0.29 Density: 0.000007850kg/mm3 5.1.1Case A(1): Load 200kgs……Bike weight inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application Von Mises Stress Deformation

5.1.2Case A(2): Load 415kgs……Bike weight+Weight of 2 persons inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application

Von Mises Stress Deformation

5.2 Modified Design-Analysis using material Beryllium Copper Material Properties: Young’s Modulus (EX): 280000N/mm2 Poisson’s Ratio (PRXY): 0.285 Density: 0.000001850kg/mm3 5.2.1Case A(1): Load 200kgs……Bike weight inclusive FOS

Geometry imported from CATIA

Meshed Model Fixed Support

Load Application

Von Mises Stress Deformation

5.2.2Case A(2): Load 415kgs……Bike weight+Weight of 2 persons inclusive FOS Geometry imported from CATIA Meshed Model Fixed Support

Load Application

Von Mises Stress

Deformation

6. RESULTS TABLE 6.1 Present Design

S.No Parameters Spring Steel Beryllium Copper Bike Bike+2Person Bike Bike+2Person 1 Stress(N/mm2) 6.6 13.6 8 16.6 2 Displacement(mm) 7.5e-3 1.6e-2 7.6e-3 1.6e-2

6.2 Modified Design

S.No Parameters Spring Steel Beryllium Copper Bike Bike+2Person Bike Bike+2Person 1 Stress(N/mm2) 6.58 13.6 6.6 13.6 2 Displacement(mm) 7.7e-3 1.59e-2 7.67e-3 1.59e-2

7.CONCLUSION

[1]. In this project we have designed a shock absorber used in a 150cc bike. We have modeled the shock absorber by using CATIA V5. [2]. To validate the strength of our design, we have done structural analysis on the shock absorber. We have done analysis by varying spring material Spring Steel and Beryllium Copper. [3]. By observing the analysis results, the analyzed stress values are less than their respective yield stress values. So our design is safe. [4]. By comparing the results for both materials, the stress value is less for Spring Steel than Beryllium Copper. [5]. Also the shock absorber design is modified by reducing the diameter of spring by 2mm and structural analysis is done on the shock absorber. By reducing the diameter, the weight of the spring reduces. By comparing the results for both materials, the stress value is less for Spring Steel than Beryllium Copper. [6]. By comparing the results for present design and modified design, the stress and displacement values are less for modified design. [7]. So we can conclude that as per our analysis using material spring steel for spring is best and also our modified design is safe.

7.REFERENCES

[1]. Machine Design by V.B.Bhandari [2].Machine Design by R.S.Khurmi [3].Automobile Engineering by R.B.Gupta